Embodiments described herein may be related to apparatuses, processes, and techniques related to multilevel dies, in particular to photonics integrated circuit dies with a thick portion and a thin portion, where the thick portion is placed within a cavity in a substrate and the thin portion serves as an overhang to physically couple with the substrate, to reduce a distance between electrical contacts on the thin portion of the die and electrical contacts on the substrate. Other embodiments may be described and/or claimed.

A semiconductor package includes a package substrate with a first vent hole, a first semiconductor chip mounted the package substrate, an interposer including supporters on a bottom surface of the interposer and a second vent hole, wherein the supporters contact a top surface of the first semiconductor chip, and the interposer is electrically connected to the package substrate through connection terminals. The semiconductor package further include a second semiconductor chip mounted on the interposer, and a molding layer disposed on the package substrate to cover the first semiconductor chip, the interposer, and the second semiconductor chip.

There is provided a semiconductor module capable of preventing the peeling of a sealing resin on the side where connection sections used for the connection to semiconductor elements are arranged. A semiconductor module includes: an outer frame; sealing resins; gate signal output terminals, and partition sections laid across the outer flame to partition a space into a plurality of housing sections, in the partition sections which the gate signal output terminals with connection sections exposed are arranged. The partition sections have first surface sections on the side where the connection sections are arranged and second surface sections formed, on the side where the connection sections are not arranged, such that the peeling strength to the sealing resins is lower than that of the first surface sections.

Techniques and mechanisms for mitigating stress on hybrid bonded interfaces in a multi-tier arrangement of integrated circuit (IC) dies. In an embodiment, first dies are bonded at a host die each via a respective one of first hybrid bond interfaces, wherein a second one or more dies are coupled to the host die each via a respective one of the first dies, and via a respective second hybrid bond interface. Stress at one of the hybrid bond interfaces is mitigated by properties of a first dielectric layer that extends to that hybrid bond interface. In another embodiment, stress at a given one of the hybrid bond interfaces is mitigated by properties of a dummy chip—or alternatively, properties of a patterned encapsulation structure—which is formed on the given hybrid bond interface.

This disclosure relates to a discrete cascode semiconductor device and associated method of manufacture, the device includes: a high voltage depletion mode device die having gate, source and drain terminals arranged on a first major surface thereof; a low voltage enhancement mode device die having a gate and a source terminal formed on a first major surface thereof, and a drain terminal formed on a second major surface opposite the first major surface. The drain terminal of the high voltage device die is mounted on a drain connection; the source terminal of the low voltage device die and the gate terminal of the high voltage device are mounted on a common source connection; and the drain terminal of the low voltage device die is mounted on the source terminal of the high voltage device.

Electronic packages and related methods are disclosed. An example electronic package apparatus includes a substrate and an electronic component. A protective material is positioned on a first surface, a second surface and all side surfaces of the electronic component to encase the electronic component. An enclosure is coupled to the substrate to cover the protective material and the electronic component.

The embodiments of the present disclosure relate to a packaging method, a panel assembly, a wafer package and a chip package. The semiconductor device packaging method includes: providing at least one wafer including a first surface and a second surface opposite to each other and a side surface connecting the first surface and the second surface, the first surface being an active surface; forming a connection portion on the side surface of the at least one wafer around the wafer, the wafer and the connection portion forming a panel assembly, the connection portion includes a third surface on the same side of the first surface of the wafer and a fourth surface on the same side as the second surface of the wafer, the third surface and the first surface forming a to-be-processed surface of the panel assembly; and forming a first dielectric layer on the first surface of the wafer. The packaging method of the embodiments of the present disclosure may improve packaging efficiency and utilization of a wafer.

In a described example, a packaged device includes a substrate having a device mounting surface including a first layer of conductive material having a first thickness less than a substrate thickness, the substrate having a second layer of the conductive material having a second thickness less than the substrate thickness. A first semiconductor device is mounted to a first area of the device mounting surface; and a second semiconductor device is mounted to a second area on the device mounting surface and spaced from the first semiconductor device. At least two connectors are formed of the first layer of the substrate having first ends coupled to one of first bond pads on the first semiconductor device and the at least two connectors having second ends coupled to one of second bond pads on the second semiconductor device.

A semiconductor package includes a first lead with first and second ends extending in the same direction as one another. At least one second lead has first and second ends and is partially surrounded by the first lead. A die pad is provided and a die is connected to the die pad. Wires electrically connect the die to the first lead and the at least one second lead. An insulating layer extends over the leads, the die pad, and the die such that the first end of the at least one second lead is exposed from the semiconductor package and the second end of the first lead is encapsulated entirely within the insulating layer.

A chip scale package structure of heat-dissipating type is provided and includes a board, a die fixed on and electrically coupled to the board, a thermally conductive adhesive sheet adhered to the die, and a package body formed on the board. The die has a heat-output surface arranged away from the board. The thermally conductive adhesive sheet is connected to at least 50% of an area of the heat-output surface. The package body covers and is connected to the die and entire of the surrounding lateral surface of the thermally conductive adhesive sheet. The die is embedded in the board, the thermally conductive adhesive sheet, and the package body. The heat-dissipating surface of the thermally conductive adhesive sheet is exposed from the package body, and a thermal conductivity of the thermally conductive adhesive sheet is at least 150% of a thermal conductivity of the package body.